A laboratory device to measure horizontal displacement of soil around a region treated by vacuum preloading includes a box injected with dredger fill. A vertical drainage board and a vacuum pumping tube are buried within soil in the treatment region in connection with a vacuum degree detector and a vacuum pump. A seal membrane covers soil in the treatment region. A loading device is above the seal membrane. transverse tubes are inserted into a side of the box and in surrounding soil of the treatment region. An annular sensing source, which moves together with the soil and which is movable along the transverse tubes, sleeved on the transverse tubes. Each transverse tube is provided with a sensing instrument, and the sensing instrument is connected with a sensor is inserted into the transverse tube. The different positions of the sensing source at different moments of time are determined.
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1. A device used in laboratories to measure horizontal displacement of soil around a region to be treated by vacuum preloading, comprising:
a box with a top surface, a bottom surface and a peripheral side surface filled with soil, the soil being divided into a central soil region to be treated by vacuum preloading and a peripheral soil region surrounding the central soil region;
a vertical drainage board and a vacuum pumping tube being buried within the soil in the central soil region, a lower end of the vacuum pumping tube being connected to the vertical drainage board and an upper end thereof being connected to a vacuum pump;
a sealing membrane above a top soil surface of the central soil region;
a loading device above the sealing membrane to assist drainage;
transverse tubes horizontally inserted into and fixed relative to the peripheral side surface of the box, a part of the transverse tubes being in the peripheral soil region;
an annular sensing source which moves with the soil of the peripheral soil region and which is movable along the transverse tubes and is sleeved on the transverse tubes, wherein a foot is extended obliquely and outwardly from the annular sensing source, by which the soil of the peripheral soil region drives the annular sensing source to move when the soil of the peripheral soil region moves due to the vacuum preloading of the central soil region; and;
a position sensing instrument with a sensing head, wherein the sensing head is adapted to be inserted into the transverse tube from outside of the box, so that when the sensing head reaches position of the annular sensing source along the transverse tubes, an alarm signal is sent, and in this way, different positions of the annular sensing source along the transverse tubes at different moments of time are determined and horizontal displacement of the soil in the peripheral soil region is calculated.
2. The device used in laboratories to measure horizontal displacement of soil around a region to be treated by vacuum preloading according to
3. The device used in laboratories to measure horizontal displacement of soil around a region to be treated by vacuum preloading according to
a sensing instrument body;
a telescopic driving device in connection with the sensing instrument body;
a telescopic rod in connection with and driven by the telescopic driving device, and the sensing head being arranged at an end of the telescopic rod;
a programmable logic controller to which the telescopic driving device and the sensing head of the position sensing instrument are operably connected, wherein the programmable logic controller is programmed to send a signal to the telescopic driving device at regular intervals to urge the telescopic driving device to drive the telescopic rod and the sensing head to do one telescopic motion forward or backward; and during the telescopic motion, the programmable logic controller records the position of the annular sensing source whenever sensed by each sensing head.
4. The device used in laboratories to measure horizontal displacement of soil around a region to be treated by vacuum preloading according to
5. The device used in laboratories to measure horizontal displacement of soil around a region to be treated by vacuum preloading according to
6. The device used in laboratories to measure horizontal displacement of soil around a region to be treated by vacuum preloading according to
a sensing instrument body;
a telescopic driving device in connection with the sensing instrument body;
a telescopic rod in connection with and driven by the telescopic driving device, and the sensing head being arranged at an end of the telescopic rod;
a programmable logic controller to which the telescopic driving device and the sensing head of the position sensing instrument are operably connected, wherein the programmable logic controller is programmed to send a signal to the telescopic driving device at regular intervals to urge the telescopic driving device to drive the telescopic rod and the sensing head to do one telescopic motion forward or backward; and during the telescopic motion, the programmable logic controller records the position of the annular sensing source whenever sensed by each sensing head.
7. The device used in laboratories to measure horizontal displacement of soil around a region to be treated by vacuum preloading according to
8. The device used in laboratories to measure horizontal displacement of soil around a region to be treated by vacuum preloading according to
9. The device used in laboratories to measure horizontal displacement of soil around a region to be treated by vacuum preloading according to
a sensing instrument body;
a telescopic driving device in connection with the sensing instrument body;
a telescopic rod in connection with and driven by the telescopic driving device, and the sensing head being arranged at an end of the telescopic rod;
a programmable logic controller to which the telescopic driving device and the sensing head of the position sensing instrument are operably connected, wherein the programmable logic controller is programmed to send a signal to the telescopic driving device at regular intervals to urge the telescopic driving device to drive the telescopic rod and the sensing head to do one telescopic motion forward or backward; and during the telescopic motion, the programmable logic controller records the position of the annular sensing source whenever sensed by each sensing head.
10. The device used in laboratories to measure horizontal displacement of soil around a region to be treated by vacuum preloading according to
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This application claims the priority benefit of Chinese Application No. 201710200805.4 filed Mar. 30, 2017, which is hereby incorporated by reference.
The present invention relates to a device, used in indoor tests where a foundation is to be treated by vacuum preloading, to measure horizontal displacement of soil around a region to be treated. The present invention also relates to a method, used in indoor tests where a foundation is to be treated by vacuum preloading, to measure horizontal displacement of soil around a region to be treated.
The foundation treatment by vacuum preloading has a great influence on the surrounding soil, especially the horizontal displacement of the surrounding soil, which may cause great harm. However, at present, during the simulation of foundation treatment in laboratories by vacuum preloading, there is no device that can measure the amount of horizontal displacement of soil around the region to be treated.
In view of the deficiencies in the prior art, a technical problem to be solved in the present invention is to provide a device which can accurately measure the amount of horizontal displacement of soil around the foundation when treated by vacuum preloading in indoor tests. The present invention also relates to a method which can measure the amount of horizontal displacement of soil around the foundation when treated by vacuum preloading in indoor tests.
For those purposes, the present invention provides a device used in laboratories to measure horizontal displacement of soil around a region to be treated by vacuum preloading, including a box; dredger fill is injected into the box; a vertical drainage board and a vacuum pumping tube are buried within soil in the region to be treated, with the vacuum pumping tube being provided with a vacuum degree detector, a lower end of the vacuum pumping tube being connected to the plastic drainage board and an upper end thereof being connected to a vacuum pump, and a seal membrane covering or wrapping soil in the region to be treated so that the interior of the seal membrane is kept sealed; a loading device is provided above the seal membrane to assist the drainage; transverse tubes are inserted into a side of the box, the transverse tubes being in surrounding soil of the region to be treated; an annular sensing source which is movable along the transverse tubes together with soil is sleeved on the transverse tubes; each of the transverse tubes is provided with a sensing instrument, and the sensing instrument is connected with a sensor which can be inserted into the transverse tube; when the sensor reaches the sensing source, an alarm signal is sent, and in this way, the different positions of the sensing source at different moments of time are determined.
The present invention further provides a method for measuring horizontal displacement of soil around a region to be treated by vacuum preloading, by using the device used in laboratories to measure horizontal displacement of soil around a region to be treated by vacuum preloading, comprising the following steps:
A: injecting dredger fill into a box of the device for measuring horizontal displacement of soil around a region to be treated by vacuum preloading; burying a vertical drainage board and a vacuum pumping tube within soil in the region to be treated, with the vacuum pumping tube being provided with a vacuum degree detector, a lower end of the vacuum pumping tube being connected to the plastic drainage board and an upper end thereof being connected to a vacuum pump, and a seal membrane covering or wrapping soil in the region to be treated so that the interior of the seal membrane is kept sealed; then activating the vacuum pump so that a negative pressure is formed below the seal membrane; and loading above the seal membrane by using the loading device to form a positive pressure;
B: inserting the sensor into the transverse tubes at regular intervals and recording the sensed position of the annular sensing source; and
C: calculating the amount of displacement of the annular sensing source according to the data of the position of the annular sensing source sensed by the sensor, detecting and obtaining the vacuum degree data by using a vacuum degree detector, calculating and loading the data by the loading device, and establishing a test model together with the amount of displacement, the loading force data, the vacuum degree data and the time span.
The present invention has the beneficial effects that the amount of horizontal displacement of soil around the region to be treated by vacuum preloading can be quickly measured; and that the measured data is accurate, the operation is simple, and the whole test device is simple in structure and low in cost.
Referring to
Referring to
Referring to
Referring to
Referring to
A: injecting dredger fill 2 into a box of the device for measuring horizontal displacement of soil around a foundation to be treated by vacuum preloading in indoor tests; burying a vertical drainage board 10 and a vacuum pumping tube 4 within soil in the region to be treated, with a lower end of the vacuum pumping tube 4 being connected to the plastic drainage board 10 and an upper end thereof being connected to a vacuum pump 5, a seal membrane 3 covering or wrapping soil in the region to be treated, an end of the seal membrane being buried so that the interior of the seal membrane is kept sealed; then activating the vacuum pump so that a negative pressure is formed below the seal membrane 3; and loading above the seal membrane 3 by using the loading device to form a positive pressure;
B: inserting the sensor 81 into the transverse tubes 6 at regular intervals and recording the sensed position of the annular sensing source 7; and
C: calculating the amount of displacement of the annular sensing source 7 according to the data of the position of the annular sensing source 7 sensed by the sensor 81, detecting and obtaining the vacuum degree data by using a vacuum degree detector, calculating and loading the data by the loading device, and establishing a test model together with the amount of displacement, the loading force data, the vacuum degree data and the time span.
Wang, Jun, Wang, Peng, Fu, Hongtao, Cai, Yuanqiang, Ni, Junfeng, Fang, Ziquan, Shi, Changxin
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